NL1009564C2 - Fast acting hydraulic valve. - Google Patents

Abstract

The invention relates to a quick switching hydraulic valve (7, 8) which opens or can be kept closed using an electric signal of low energy and which can switch very quickly with large passage. Regarding the known valves the switching valve according to the invention has the advantage that a tight embodiment with a very simple construction is possible and that spontaneous opening or spontaneous closing cannot occur in actual circumstances. Additionally the switching as regards timing is less critical and leakage via the controlling auxiliary valves (1, 2) or via internal leakage connections does not occur.

Description

Fast acting hydraulic valve

The invention relates to a hydraulic switching valve which can open very quickly from the closed position by means of a usual electrical signal of very low energy.

Valves with these properties are known from patent applications PCT / NL 96/00157 dated 10-4-96 and PCT / NL 95/00260 dated 27-7-95.

The first application concerns a valve that is operated by a so-called adjusting piston which can move the valve body quickly after an electrical signal of low energy. The adjusting piston forms, with the adjusting cylinder, a first and a second displacement space, in the first position the first and the second displacement space are connected at low pressure. From that first position, the adjusting piston can move freely, apart from an existing spring force, but after a small initial movement the first displacement space is connected by the adjusting piston to the high pressure Ph and thereby moves to the second position. The adjusting piston can drive a wide variety of valve types with an almost unlimited number of switching functions. In case a simple on-off valve is driven, a fast-acting hydraulic switching valve is created. A drawback of this valve remains that through the slit seals of the adjusting piston, leakage occurs from the main supply with high pressure Ph, so that a tight-fitting hydraulic switching valve cannot be realized in this way. In some of the known embodiments, a relatively heavy valve spring is also required to keep the actuated valve closed.

In PCT / NL95 / 00260, the valve body has two sealing edges which form three chambers with the valve body in the closed position, the first chamber always being connected to the high supply pressure Ph, the second chamber in the closed position also being connected to the high pressure Ph and the third chamber at the outlet of the valve with outlet pressure Pu. This outgoing pressure Pu can in principle lie between Ph and the low system pressure PI.

The valve will open spontaneously as a result of only the input and output pressures but can be held in the closed position by high pressure Ph in the second chamber acting on the second surface of the valve body which area is larger than the first area of the valve. the valve body on which the high pressure Ph acts in the first chamber.

The valve will open as soon as the second chamber is connected to low pressure PI via existing switching means. Since only very little liquid transport is required to allow the pressure in the second chamber to drop sufficiently, these are switching means of small diameter which can thereby react quickly to an electrical signal of low energy. As soon as the pressure in the second pressure chamber has dropped sufficiently, the valve will open under the influence of the pressure Ph on the first surface of the valve body.

A drawback of the valve from PCT / NL 95/00260 is that the two seat seals of the »1 009564 2 valve body must close exactly simultaneously with the intended pot-tight design and must therefore meet very high mechanical machining tolerances. In order to solve this problem, in the preferred embodiment, the valve body is built up of two parts which can move relative to each other and which are separated via a slit seal. However, as a result of this intervention 5 the complexity increases, the opening force decreases (because a permanently working closing complaint is created under the influence of the high pressure) and a leak gap is created between the two valve parts.

A second drawback is that after opening a connection is created between the high pressure supply and the low pressure P1 via the opened and electrically operated switching valve 10, with which the second chamber is connected at low pressure. The period during which this electrovalve must remain open is critical because a reliable minimum switching time of the hydraulic switching valve is required for reliable operation of the hydraulic valve, while on the other hand the shortest possible opening time is required to prevent too much leakage via the opened electrovalve to level PI.

A third drawback of this switching valve is that it can close spontaneously for a short or longer period of time after a short pressure increase in the outgoing pipe to the level Ph. Such an increase in pressure can easily be caused by closing an existing intermediate valve further down in the outgoing pipe to, for example, the hydrocylinder to be operated, or by a loading of this cylinder occurring. Due to the high pressure in the outgoing pipe, a pressure equilibrium is created in the valve housing, whereby the spring will close the valve. When subsequently the load of the connected cylinder is lost again or the intermediate valve is opened, Pu will drop quickly and this creates the situation with high pressure in the first and second chamber and low pressure in the third chamber, and these are the same conditions that exist in the closed position. the electrovalves are maintained to keep the valve closed.

A safety objection in some applications of this valve can also be the fact that the valve will open immediately if the high control pressure in the second chamber should drop for a moment due to unforeseen causes. Without this control pressure in the second chamber commanded by the electrovalves, the valve acts as a non-return valve which opens spontaneously and immediately upon pressure on the inlet of the valve.

The object of the invention is to provide an alternative to a fast-acting hydraulic switching valve with which the occurring disadvantages of the known switching valves can also be prevented.

The hydraulic switching valve according to the invention differs in that the adjusting piston is missing from the valves moved by an adjusting piston described in PCT / NL96 / 00157.

Compared with the valve described above from PCT / NL95 / 00260, the valve p1 009564 3 according to the invention is distinguished in that in the known configuration of valve and valve body the connections of the valve housing are changed in the sense that the third pressure chamber is always connected to the inlet 16 of the valve with high pressure Ph instead of with the outlet pressure Pu, while in the closed position the first chamber is connected with low pressure 5 instead of with the high pressure Ph. In addition, switching means are present in all embodiments which can connect the first instead of the second chamber with high or low pressure. The design and dimensioning of the valve body differs, inter alia, in that the first surface 9c is larger than the second surface 10c instead of the other way round. The valve according to the invention also has two main embodiments.

In the first embodiment of Figure 1, the second chamber 10 is permanently connected to the outlet 17 of the valve with pressure Pu.

In the second embodiment, the first chamber 9 is always connected to the outlet 17 of the valve with pressure Pu and the second chamber 10 is always connected to low pressure Ps2, the second sealing edge being designed as a gap seal 10b to which the tight-fitting seat seal 10a is added. The design is such that the gap seal 10b seals permanently between the second and third chambers 10 and 11.

The above-mentioned drawbacks do not occur with the new switching valve that is created in this way, which will be briefly explained in the following.

20 The leakage losses via the adjusting piston do not occur because the adjusting piston is missing. A very light valve spring is always sufficient because in all cases, even without resilience, the switching valve is kept safely in the closed position.

The leakage losses via the electric switching valve 1 to PI do not occur because switching is done from PI to Ph. The switching period is therefore no longer critical.

The chance of a spontaneous closing of the hydraulic switching valve is absent, because in the first embodiment according to figure 1, from the position of pressure equilibrium between Ph and Pu and a valve closed by the spring force, the closing force also disappears when the pressure Pu is released. exerted by the pressure Pu on the second surface 10c of the valve body. The loss of this closing force therefore means in this case that the resulting opening force on the valve body increases, so that an undesired spontaneous closing cannot occur.

In the embodiment according to Figure 2, spontaneous closing does not occur either, because before closing the pressure Ps2 must first become higher than the pressure in the input line 16 and this condition cannot occur spontaneously.

The measures described in PCT / NL95 / 00260 to realize a simultaneous tight seal of the two seat seals are also not necessary with the hydraulic switching valve according to the invention. Instead, the valve body is dimensioned such that it elastically deforms under the influence of the pressure Ph in the third chamber on the valve body, whereby the two closing edges seal tightly.

The valve according to the invention is further intrinsically safe because no pressure is required in the first chamber to keep the valve closed. The valve according to the invention is always kept firmly closed under the influence of the high inlet pressure Ph on the valve part 7a, even if control pressure P $ or even when the valve spring breaks.

The characteristic of the hydraulic switching valve according to the invention is that switching means (1 and 2) are present for connecting the first chamber (9) with high or low pressure (PsMPh or Ps), the first chamber (9) being in the closed position of the valve is connected to low pressure (PI) and the third chamber (11) is always connected to the high inlet pressure (Ph) while the first surface (9c) of the valve body is greater than or equal to the second surface! 10c).

The invention is described below with reference to Figure 1, which gives Figure 15 a characteristic first embodiment and with reference to Figure 2 which gives a characteristic second embodiment.

In Figure 1, 8 is the valve body in which the valve body 7a, 7b moves between the drawn closed or closed position and the position where the valve is fully opened. The valve body 20 here consists of two parts 7a and 7b which are connected to each other via a guide rod. Under the influence of the valve spring 6, the valve body will experience a force towards the closed position. The first and second sealing edges 9a and 10a of the valve body close with a tight-fitting seat seal against the valve body and thereby form three chambers 9, 10 and 11 in the closed position. The first sealing edge 9a seals between the first chamber 9 and the third chamber 11 The second sealing edge seals between the second chamber 10 and the third chamber 11. The pressure in the first chamber 9 is applied to the first surface 9c of the valve body while the surface 10c experiences the pressure in the second chamber 10. Furthermore, the first chamber 9 in the closed position connected to low pressure P1 via the auxiliary valve 1 which is a generally electrically operated valve with a small diameter and thereby a very high switching speed. The pressure PI is a low system pressure. The first chamber 9 can be connected to the pressure Ps or PI with the switching means 1 and 2, Ps being a pressure level which lies between the low system pressure PI and the high system pressure Ph. In general, Ps is equal to Ph.

The second chamber 10 is permanently connected to the output 17 of the hydraulic switching valve with pressure Pu, which may have values between PI and Ph. The third chamber 11 is permanently connected to the valve 16 with high system pressure Ph.

The valve works as follows. In the closed position, the first chamber 9 is connected to low pressure PI via auxiliary valve 1, whereby auxiliary valve 2 is closed. In the third chamber 11, the pressure Ph exerts a closing force on the valve part 7a and an opening force on the valve part 7b. Because the first surface 9c is larger than the second surface 10c, the closing force is greater than the opening force, so that a resultant closing force is exerted on the valve body under the influence of the pressure in the third chamber 11.

At low pressure PI in the first and second chambers 9 and 10, no resultant force is exerted on the valve body via the first and second surfaces 9c and 10c so that the hydraulic switching valve remains closed.

At pressure Ps in the first chamber 9 by closing auxiliary valve 1 and opening auxiliary valve 2, an opening force will be exerted on the valve body 10 via the first surface 9c, as a result of which the valve opens. As a result of the opening, the pressure on the first surface 9c rises to the level Ph and the valve opens further.

The pressure Ps is higher than PI and generally equal to Ph. Opening also requires Ps to be high enough to overcome the closing force created by the pressure Pu on the second surface 10c.

When Ps is lower than Ph it is desirable to include a non-return valve between auxiliary valve 2 and the pressure source Ps to prevent liquid from flowing from the third chamber with pressure Ph to the pressure source with the lower pressure Ps when the valve is open.

When, after opening the valve, a pressure equilibrium is created between Ph and Pu, the valve will close under the influence of the valve spring 6. In the event that Pu should subsequently drop rapidly, the valve will open at an accelerated rate because the closing force via the second surface 10c then also decreases rapidly, resulting in a resulting opening force.

From the situation with pressure equilibrium between Ph and Pu and a valve closed by the valve spring, the valve can be kept in the closed position by closing auxiliary valve 2 and opening auxiliary valve 1, causing the pressure in the first chamber 9 to drop and the initial state 25. has been reached again.

In case the valve outlet 17 would be connected at high pressure and the valve inlet 16 at low pressure, the valve will immediately close due to the pressure difference over the valve part 7b and the resulting closing force.

The auxiliary valves 1 and 2 are generally fast switching solenoids with small bore. Auxiliary valve 1 can also be a pressure-switched valve that closes above a certain low pressure value in line 3 and opens as long as and as soon as the pressure in line 3 drops below that threshold.

In order to achieve a tightly closing hydraulic switching valve, it is necessary that the two sealing edges with the seat seals 9a and 10a both close simultaneously. This requires extremely precise mechanical machining tolerances of the valve and valve body. In order to avoid these narrow tolerances, the valve body of the invention according to the invention has the valve body processed in such a way that when the valve is closed and the valve body is pressureless, one of the r '* 1009564 6 sealing edges 9a or 10a does not close. The valve part 7a is a relatively flexible slack which will bend under the influence of the pressure Ph in the third pressure chamber until both sealing seats close. In the preferred embodiment, the valve body is machined such that the first sealing edge 9a first closes, after which under the influence of the pressure Ph in the third chamber 11 the middle part of the disc-shaped valve part 7a bends to the left, whereby valve part 7b is pulled to the left by the connecting rod and the second sealing edge 10a will also close. When the shape of the valve body is such that first the second sealing seat 10a closes, under the influence of the pressure Ph in the third chamber, the outer edge of the disc-shaped valve part 7a will bend to the left, whereby the first sealing seat 9a also closes.

Another way to achieve a tight seal is to replace one of the seat seals with an o-ring seal that allows some variation in the gap height or with an elastic metal lip seal where the metal lip under the influence of the pressure in the third pressure chamber.

15

Figure 2 is very similar to Figure 1. A difference is that the second sealing edge 10a, b and d forms two seat seals 10a and 10d and a slit bar seal 10b with the valve body 8. The slit seal 10b with the valve housing remains permanently, whereby in fact the valve part 7b will function as a piston in a cylinder with two displacement spaces 14 and 15. The function of the piston is to exert a permanent opening force on the valve body and for this purpose the first displacement space 14 is permanently connected to the high pressure Ph and the second displacement space 15 is permanently connected to the low control pressure Ps2, which is substantially equal to the low system pressure P1.

In this embodiment, the first chamber 9 is permanently connected to the outlet 17 with pressure Pu.

The valve part 7b is also provided with a second seat edge 10d with which, in the fully opened right-hand position, the large pipe 18 is closed to pressure level Ps2.

The hydraulic switching valve works as follows. In the closed position, the valve body is kept closed under the influence of the pressure Ph in the third chamber 11 on the valve part 7a. The closing force resulting from this is greater than the permanent opening force created by the high pressure Ph in the space 14 exerted on the valve part 7b. The valve is opened by admitting the high control pressure Ps to the first chamber 9 via auxiliary valve 2 in the manner described in figure 1. The control pressure Ps must in any case be high enough to allow the closing force on valve part 7b as a result of overcome the pressure of Ps2. In general, Ps is equal to Ph and Ps2 is equal to the low pressure PI.

When the valve is fully opened, leakage to the pressure level Ps2 is prevented because the seat edge 10d seals against the valve housing 8 and thereby completely closes line 18.

* 1009564 7

When the valve is closed, a tight seal is achieved by elastic deformation of the valve body under the influence of the pressure Ph in the third chamber 11 in the manner described in Figure 1. It is also possible to use the above-mentioned o-ring or the metalic seal here instead of the seat seal 9a.

In order for this embodiment to function properly, it is necessary that pressure can build up in the valve discharge pipe 17 when the valve is closed.

The practical difference between version 1 and version 2 is in particular that in version 2 flow is possible in two directions through the switching valve because the valve remains open at pressure equilibrium between Ph and Pu, while in the embodiment according to figure 1 the valve in that case is the spring force will move to the left closing position. In order to definitively close version 1, the first pressure chamber 9 is connected to low pressure via auxiliary valves 1 and 2, based on an existing pressure equilibrium between inlet and outlet 16 and 17. In order to permanently close version 2, it must first be ensured that Ps2 becomes higher than the pressure in lines 16 and 17, as a result of which the valve moves to the left closing position, after which the first 15 chamber is connected to the auxiliary valves 1 and 2 at low pressure.

The practical difference between the two embodiments is manifested, for example, when the fast hydraulic switching valve according to the invention is used as a starting valve for starting a free piston engine of the type described in the aforementioned two patent applications.

In case embodiment 1 is applied, the pressure Pca is connected to the valve inlet 16 and the pressure Pcc is connected to line 17. The switching valve will then close during the expansion stroke of the free piston as soon as Pcc exceeds Pca.

In case embodiment 2 is applied, the pressure Pca is reconnected to line 16 and Pcc to line 17, but line 18 is now connected to the pressure Pac in the working cylinder. The switching valve will now close during the expansion stroke as soon as Pac exceeds Pca whereby closing can be delayed by connecting Pac via a check valve to line 18 and bypassing this check valve by means of a restriction. When closing, the liquid from space 15 must then flow through the restriction, so that the closing of the switching valve can be delayed, with the advantage that flow can also take place from the hydraulic compression cylinder to the compression during the first part of the expansion stroke of the free piston. accumulator.

Furthermore, for both embodiments, the auxiliary valve 1 could be omitted under certain circumstances. This situation occurs when a certain leak to low pressure is already present from the first chamber or when the hydraulic switching valve always has to be closed for such a short time that the pressure in the first chamber in that short time is not due to leakage via the first sealing edge 9a high enough • 1 009564 8 can rise to open the switching valve early. 5 10 15 20 25 30 35 p1009564

Claims (10)

Hydraulic switching valve, consisting of a valve body (8) containing a valve body (7a, 7b) movable between an open and closed position, which generally experiences a permanent spring force in the direction of the closed position, whereby at the inlet (16 ) the valve has a high pressure level Ph and at the outlet (17) the outlet pressure Pu, which may have values between the low system pressure Pl and the high pressure Ph, the valve body having a first (9a) and a second sealing edge (10a, b, d) has 10 and thus forms three closed chambers (9, 10 and 11) in the closed position of the valve with the valve body, the first sealing edge (9a) sealing between the first chamber (9) and the third chamber (11) and seals the second sealing edge between the third chamber (11) and the second chamber (10), the valve body having a first surface (9c) on which pressure is applied in the first chamber, which pressure is a force in the direction of the open position and a second surface (10c) on which the dich The pressure is exerted in the second pressure chamber (10), whereby a force is created in the direction of the closed position, characterized in that switching means (1 and 2) are present to connect the first chamber (9) to high or low pressure (Ph os Ps), where in the closed position the first chamber (9) is connected to low pressure (Pl) while the third chamber (11) is always connected to the high inlet pressure (Ph) and the first surface ( 9c) of the valve body is greater than or equal to the second surface (10c). Hydraulic switching valve according to claim 1, 30, characterized in that the second chamber (10) is always connected to the outlet (17) of the switching valve with pressure Pu. •• 10 09 56 4 Hydraulic switching valve according to claim 1, characterized in that the first chamber is always connected to the outgoing pipe (17) and the second chamber (10) is always connected to the pressure Ps2 which is lower than Ph and preferably equal to Pl, the second sealing edge with a gap seal (10b) permanently sealing against the valve body. Hydraulic switching valve according to claim 3, characterized in that the second sealing edge is also provided with a first seat seal (10a) which seals against the valve housing in the closed position of the valve. Hydraulic valve according to claim 3 or 4, characterized in that the second sealing edge is also provided with a second seat seal (10d) which seals line 18 when valve 15 is fully opened. Hydraulic switching valve according to any one of the preceding claims, characterized in that the valve body is dimensioned such that in the closed position at pressure equilibrium in the valve body, only the seat seal 20 (9a) of the first sealing edge or the first seat seal (10a ) of the second sealing edge, wherein the valve body is also designed in such a way that due to elastic deformation of the valve body under the influence of the high supply pressure (Ph) in the third chamber (11) both seat seals (9a, 10a) both close Hydraulic switching valve according to claim 5, characterized in that the valve body consists of a first disc-shaped or plate-shaped part (7a) and a second disc or plate-shaped part (7b) connected by a connecting rod, at least one of the parts preferably the larger part (7a) is so flexible that in the closed position it will bend under the influence of the high supply pressure (Ph) in the third pressure chamber to such an extent that both seat seals are closed. Hydraulic switching valve according to any one of claims 1 to 4, characterized in that the seat of the first sealing edge (9a) or the first seat (10a) 1 * 10 09 5 6 4 of the second sealing edge is replaced by an o-ring seal or an elastic and metallic seal that seals in the closed position under the influence of the pressure in the third chamber. Hydraulic switching valve according to any one of the preceding claims, characterized in that it is used as a starting valve for a free-piston unit as described in patent applications PCT / NL95 / 00260 and PCT / NL96 / 00157. Start valve according to claim 9, characterized in that with a valve according to claim 2 the pressure Pca is connected to the valve inlet (16) and the pressure Pcc to the valve outlet (17), while with a valve according to claim 3 the pressure Pca is connected to the valve inlet (16), the pressure Pcc to the valve outlet (17) and the pressure Pac on line (18) to the second pressure chamber. -o-o-o-o-o-o-o-o- ü10 09.5 6 4